Math 259 Winter 2009. Recitation Handout 1: Finding Formulas for Parametric Curves



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Transcription:

Math 259 Winter 2009 Recitation Handout 1: Finding Formulas for Parametric Curves 1. The diagram given below shows an ellipse in the -plane. -5-1 -1-3 (a) Find equations for (t) and (t) that will describe this curve. Use the interval 0 t 2π. (b) How would ou modif our answer to Part (a) if onl the right hand half of the ellipse was needed? (c) How would ou modif our answer to Part (b) if the initial and terminal points of the curve are reversed?

2. Consider the line segment shown in the diagram below. 4 3 2 1 0 0 1 2 3 4 5 6 7 (a) Find a pair of parametric equation and an interval of t-values that correspond to the line segment pictured above, and that line segment onl. (b) Suppose the lowest t-value in our interval is t = a. Sketch the graph ou would get if ou were to plug values of t that are less than t = a into our parametric equations from Part (a). (c) Suppose the highest t-value in our interval is t = b. Sketch the graph ou would get if ou were to plug values of t that are less than t = b into our parametric equations from Part (a). (d) Find a pair of parametric equations that specif the straight line that passes through the point (1, 1) and is perpendicular to the line segment pictured above.

3. The Earth orbits the sun with an orbital path that is actuall an ellipse, but which is so close to being a circle that we will assume that the orbital path is circular. The Moon orbits the Earth in an orbit that is also ver close to being circular (so we will assume it to be a circle also), as shown in the diagram 1 given below. Throughout this problem we will assume that t represents the number of das after midnight on Januar 1. (a) The mean distance from the Earth to the Moon is 384,400 km. Suppose that at time t = 0 the Moon starts at the point labeled Apogee in the above diagram and starts to orbit the Earth in a counterclockwise direction. Imagine that the Earth is fied at the point (0, 0) of the -plane. Find a pair of parametric equations to describe the motion of the Moon around the Earth. 1 Image courtes of NASA, http://www.nasa.gov

(b) The mean distance from the Earth to the Sun is 149,600,000 km. Suppose that at time t = 0 the Earth starts at the point labeled Perihelon in the diagram (above) and immediatel starts to orbit the Sun in a counterclockwise direction. Imagine now that the Sun is fied at the point (0, 0) of the -plane. Find a pair of parametric equations to describe the motion of the Earth around the Sun. (c) Imagine again that the Sun is fied at the point (0, 0) of the -plane and that at time t = 0 the Moon starts at the point labeled Apogee on the above diagram. Bearing in mind that the Moon orbits the Earth and the Earth orbits the Sun, find a pair of parametric equations to describe the motion of the Moon around the Sun.

4. In a search and rescue mission, a Coast Guard cutter is searching for a acht that is lost in the fog and in a state of distress. Imagine that the area of ocean that the fog covers is like the -plane. Let t be the number of hours that have passed since the acht was reported overdue and the Coast Guard search began. The position of the acht at time t is given b the pair of parametric equations: Y ( t) = 4t " 4 and Y ( t) = 2t " k, where k is a constant. The position of the Coast Guard cutter at time t is given b the pair of parametric equations: ( t) = 3t and t CG CG ( ) = t 2 " 2t "1. (a) If it is determined that k = 5, does the Coast Guard ever find the acht? (b) Find the values of k that result in the Coast Guard eventuall finding the acht. (c) At the time that the Coast Guard finds the acht in Part (b), which vessel is sailing the fastest? (Your answer ma contain the constant k.)

5. A hpotrochoid is a curve formed when a circle rolls around inside another circle, like the ball in a game of roulette rolling around the track of the roulette wheel. Formall, imagine a point on the edge of a circle with radius a (with 0 < a) that rolls around the inside of another circle of radius b (with 0 < a < b) as shown below. The curve traced out b the point on the smaller circle as the small circle rolls around is the hpotrochoid. The small circle turns in this direction as it rolls The small circle advances in this direction as it rolls The point on the small circle that traces out the hpotrochoid (a) Use the diagram provided below to sketch the hpotrochoid. a b

(b) Find a pair of parametric equations ((θ) and (θ)) that describe the hpotrochoid. It is fine for our equations to include the constants a and b. NOTE: The suggested parameter, θ, is the angle between the line segment joining the centers of the two circles and the -ais, as shown in the diagram below. If ou believe that another parameter will be easier to use, feel free to use it but make sure ou define the alternative parameter clearl when ou write down our solution

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